DE4212934A1 - Optical signal receiver circuit - has collector emitter of bipolar transistor connected in parallel with trans-impedance amplifier coupling resistance - Google Patents

Abstract

The receiver has a photodiode (PD) and a trans-impedance amplifier (1). The diode (PD) is connected in a d.c. circuit including a voltage supply (UB) and the amplifier input. A coupling resistance (RF) is connected between the input and output of the amplifier (1). The collector emitter path of a silicon bipolar transistor (T1) is connected across the coupling resistance (RF). The transistor (T1) is driven below saturation voltage. Thus, noise and sensitivity are varied only negligibly. The collector emitter resistance is varied by a control circuit (2) in dependence on the output voltage (Ua) of the amplifier (1) via the base current of the transistor (T1). ADVANTAGE - Ensures good reception of all signals with neither loss nor transmission delay.

Description

The invention relates to a circuit arrangement for an optical Receiver used as an optical communication system opto-electrical converter is used. Such recipients usually consist essentially of a photodiode and a downstream amplifier with negative feedback resistor, a so-called transimpedance amplifier. Light quanta that on the Impact photodiode, generate a photocurrent from the Transimpedance amplifier amplified and as its output voltage is processed further. In the first approximation, the product determines Photocurrent and negative feedback resistance of the transimpedance amplifier the value of the output voltage.

In optical communication systems, the Power level of the optical signals to be processed very much assume different values. The optical receiver must therefore be able to get relatively low as well as very high power levels to be detected without errors. The lower limit is called Receiver sensitivity. It becomes essential from the Noise characteristics of the photodiode and the transimpedance amplifier certainly. The upper power level is caused by the overload of the Transimpedance amplifier limited. Between those through this Conditions determined minimum and maximum power levels of the Received signal lies the so-called dynamic range of the optical  Recipient. It is often desirable to review this dynamic range expand above, so that the optical receiver even at large optical reception services is to be operated. To solve this Problems are already a variety of circuit variants have been specified. For example, it is known to enter the Transimpedance amplifier to connect a diode in parallel, cf. DE-32 18 439. Likewise, an arrangement with a parallel Field effect transistor known, cf. EP 0 181 146. For large Power level of the optical signals and correspondingly large these additional elements are conductive, so that part of the photocurrent from the input of the transimpedance amplifier is derived. The change in resistance can be self-controlling or done externally. Such additional wiring on The input of the transimpedance amplifier always requires one additional capacity and thus a deterioration in Noise characteristics so that the receiver sensitivity decreases.

Another option is to expand the dynamic range in making the negative feedback resistance dependent on Varying input photostream. It is known to the Negative feedback resistor to connect a diode in parallel or to Negative feedback to use a resistor diode network, cf. EP 0 177 217. Furthermore, it is known as a negative feedback resistor use an active component directly, for example one Field effect transistor, cf. DE 32 33 146. In the aforementioned Circuit arrangements become effective with increasing input current Negative feedback resistance is reduced by the active element is becoming increasingly leading. That does indeed increase the Output voltage counter, the overdrive of the Transimpedance amplifier is prevented, but with the previously known arrangements occur due to the current-dependent Two-pole transmission behavior signal distortion on how for example in the case of a diode due to its current-dependent differential resistance. External control of the diode leaves  only with AC voltage coupling to the Realize transimpedance amplifier. With DC coupling there is a self-control of the diode, which is then particularly the relatively high diffusion capacity interferes. This will the noise of the receiver increases and its bandwidth reduced.

The invention is based on the object, a monolithic integrable preamplifier with extended dynamic range specify which can be implemented in silicon bipolar technology and the above-mentioned disadvantages of known circuit arrangements avoids.

This object is achieved by the circuit arrangement specified in claim 1. In this circuit arrangement, a silicon bipolar transistor connected in parallel with its collector-emitter path to the negative feedback resistor is used as a variable resistor. Since the silicon _{bipolar transistor is} operated with collector-emitter voltages below the collector-emitter saturation voltage U _CEsat , the collector-emitter resistance can be adjusted via the base current.

It is possible to split the negative feedback resistor into two sub-resistors split and with the silicon bipolar transistor only the am To bridge the second partial resistor located at the amplifier output. This variant has the advantage that there is always a Part of the negative feedback resistor remains effective and thus the Vibration tendency of the amplifier if the negative feedback is too strong counteracts. On the other hand, the Capacitance of the collector base diode from the amplifier input kept away, so that a deterioration of the Noise characteristics is avoided.  

With a further circuit variant, an enlargement of the output voltage range is possible. When a silicon _bipolar transistor is connected in parallel with the negative feedback resistor, the output voltage of the optical amplifier in the present solution is limited to the saturation _voltage U _{CEsat of} the transistor. By dividing the negative feedback resistor into several partial resistors, a silicon bipolar transistor can be connected in parallel to each partial resistor, so that the output voltage can then be a multiple of the saturation voltage depending on the number of transistors.

Thus, an optical receiver with a large dynamic range specified, which is completely DC-coupled and in Silicon bipolar technology can be integrated monolithically and in which the expansion of the dynamic range without significant loss Receiver sensitivity is enabled.

The invention is illustrated below using an exemplary embodiment explained. Show in the accompanying drawing

Fig. 1 is a circuit diagram of the circuit arrangement according to the invention,

Fig. 2 is a circuit diagram of the circuit arrangement according to the invention with divided negative feedback resistor and

Fig. 3 is a circuit diagram of a variant of the circuit arrangement according to the invention.

Referring to FIG. 1, the circuit arrangement for an optical receiver from a photodiode PD and an amplifier 1 having negative feedback resistor R _F a for this parallel-connected transistor T1 and of a control circuit 2, which includes a differential amplifier 3, and a voltage Reviewer 4.

The magnitude of the output voltage U _{a of} the amplifier 1 is monitored by a voltage evaluator 4 . This consists either of a low-pass filter, with which a control voltage is obtained from the mean value of the output voltage U _a , or of a rectifier, with which a control voltage is obtained from the peak value of the output voltage U _a . This detected voltage is compared in a differential amplifier 3 with a reference voltage U _ref . The reference voltage U _ref is expediently chosen such that it corresponds to the detected voltage at an input signal _peak current I _ph = U _CEsat / R _F.

In the case of light _powers which are converted into photocurrents I _ph <U _CEsat / R _F by means of the photodiode PD, the control circuit 2 does not supply a base current, the base voltage is below the collector or emitter potential and the transistor T1 is thus blocked. The full negative feedback resistance R _F then acts. The transistor T1 influences the noise power and the bandwidth of the optical receiver only slightly, since no current flows through it and the additional capacitances due to the blocked base collector and base emitter diodes are relatively small.

If the light output exceeds a value that generates photocurrents I _ph <U _CEsat / R _F in the photodiode PD, the voltage generated by the voltage _{evaluator falls} below or exceeds the reference voltage U _ref at the differential amplifier 3 and the output voltage of the control circuit 2 is increased so far , until a base current flows into the transistor T1 connected in parallel with the negative feedback resistor R _F. The transistor T1 thus becomes conductive and part of the photocurrent I _ph at the input of the amplifier 1 flows over its collector-emitter path. The differential resistance of the collector-emitter path is now connected in parallel to the negative feedback resistor R _F. A further increase in the photocurrent I _ph causes an increase in the base current via the control circuit 2 and thus a reduction in the differential resistance and consequently also a reduction in the total negative feedback resistance. This counteracts an increase in the output voltage U _{a of} the amplifier 1 and thus an overload of the amplifier 1 .

The maximum output voltage U _{a of} the amplifier 1 is limited to the value U _CEsat . Larger output voltages U _a can be achieved if the negative feedback resistor R _F consists of a series connection of several resistors R _F1 , R _F2 , R _Fn and each resistor, the collector-emitter path of a transistor T1, T2, Tn is connected in parallel, as is the case is shown in Fig. 3.

Fig. 2 shows the possibility of the negative feedback path of two partial resistors R _F1, R _F2 to form and only a partial resistor R _F2 with the collector-emitter path of a transistor bridge. This results in an optimization possibility of the circuit arrangement in the event that a minimum resistance value in the negative feedback branch should not be undercut.

The circuit arrangement according to the invention and its variants can also be used if the cathode of the photodiode PD is connected to the input of the amplifier with a different polarity of the supply voltages. It is then only necessary to interchange the connections of the collector and emitter of the transistor T1 at the negative feedback resistor R _F.

Claims (5)

1. Circuit arrangement for an optical receiver, which contains a photodiode (PD) and an amplifier ( 1 ), the photodiode (PD) being in a direct current circuit comprising the supply voltage source (U _B ) and the input of the amplifier ( 1 ) and between the input and output the amplifier ( 1 ) has a negative feedback resistor (R _F ), characterized in that the collector-emitter path of a silicon bipolar transistor (T1) is connected in parallel with the negative feedback resistor (R _F ) and that between the output of the amplifier ( 1 ) and the base of the silicon bipolar transistor (T1) is a control circuit ( 2 ). 2. Circuit arrangement for an optical receiver according to claim 1, characterized in that the silicon bipolar transistor (T1) operated below its collector-emitter saturation voltage becomes. 3. Circuit arrangement for an optical receiver according to claim 1, characterized in that the control circuit ( 2 ) contains a differential amplifier ( 3 ), at the first input of which there is a voltage evaluator ( 4 ), the input of which is connected to the output of the amplifier ( 1 ) and at its second input there is a reference voltage (U _ref ), the size of which is selected so that it corresponds to the detected voltage at an input signal peak current of the optical receiver. 4. Circuit arrangement for an optical receiver according to claim 2, characterized in that the voltage evaluator ( 4 ) for evaluating the mean value of the output voltage of the amplifier ( 1 ) consists of a low-pass filter or that the voltage evaluator ( 4 ) for evaluating the peak value of the output voltage of the amplifier consists of a peak detector. 5. Circuit arrangement for an optical receiver according to claim 1, characterized in that the negative feedback resistor (R _F ) consists of a series connection of at least two partial resistors (R _F1 , R _F2 , _... , R _Fn ) and that to a certain number of Partial resistors each have the collector-emitter path of a silicon bipolar transistor (T1, T2, ..., Tn) connected in parallel and that the base connections of the silicon bipolar transistors are connected to a control circuit ( 2 ).